A modular energy storage cabinet, and a system including same, may include an AC connection port capable of connecting to an AC bus, and a plurality of battery modules, an inverter, and a plurality of busses, wherein the plurality of busses electrically connect the plurality of batteries to each other and to the positive DC input and negative DC input of the inverter to effectuate a voltage.
Legal claims defining the scope of protection, as filed with the USPTO.
1. A modular energy storage cabinet comprising: an AC connection port capable of connecting to an AC bus; a plurality of battery modules, each battery module comprising a battery, a positive terminal and a negative terminal; an inverter having a positive DC port, a negative DC port, and an AC port; and a plurality of busses having at least one internal bus;, wherein the plurality of busses electrically connect the plurality of batteries to each other and to the positive DC input and negative DC input of the inverter to effectuate a voltage, wherein the at least one internal bus of the plurality of busses connects the positive terminal of a first battery module to the negative terminal of a second battery module.
2. The modular energy storage cabinet of claim 1 wherein each battery module further comprises a DC-to-DC converter connected to the battery and to the positive and negative terminal of the respective module.
3. The modular energy storage cabinet of claim 1 wherein the plurality of busses comprises a positive bus and a negative bus, and wherein negative terminal of each battery module of the plurality of battery modules is connected to the negative DC port of the inverter by the negative bus, and positive terminal of each of the battery modules of the plurality of battery modules is connected to the positive DC port of the inverter by the positive bus.
4. The modular energy storage cabinet of claim 1 wherein the plurality of busses comprises a positive bus, and a negative bus, and wherein negative terminal of the first battery module of the plurality of battery modules is connected to the negative DC port of the inverter by the negative bus, and positive terminal of a last module of the plurality of battery modules is connected to the positive DC port of the inverter by the positive bus, and wherein the at least one internal bus connects each of the battery modules in the plurality of battery modules in series from the first battery module to the last battery module.
5. The modular energy storage cabinet of claim 1 wherein the plurality of busses comprises a positive bus and a negative bus, and the plurality of battery modules comprises a first set of battery modules and a second set of battery modules, wherein the first set and the second set are different; wherein negative terminal of the first set is connected to the negative DC port of the inverter by the negative bus, and positive terminal of the last set is connected to the positive DC port of the inverter by the positive bus, and wherein the at least one internal bus connects each of the sets of battery modules of the plurality of battery modules in series from the batteries in the first set to the batteries in the last set of battery modules.
6. The modular energy storage cabinet of claim 5 wherein the plurality of sets of battery modules further comprises an intermediary set of battery modules between the first set of battery modules and the last set of battery modules.
7. A modular energy storage cabinet comprising: an AC connection port capable of connecting to an AC bus; a plurality of battery modules, each battery module comprising a battery, a positive terminal and a negative terminal; an inverter having a positive DC port, a negative DC port, and an AC port; a plurality of busses, wherein the plurality of busses electrically connect the plurality of batteries to each other and to the positive DC input and negative DC input of the inverter to effectuate a voltage; and a circuit breaker in electronic communication with the AC port of the inverter and the AC connection port.
8. A modular energy storage cabinet comprising: an AC connection port capable of connecting to an AC bus; a plurality of battery modules, each battery module comprising a battery, a positive terminal and a negative terminal; an inverter having a positive DC port, a negative DC port, and an AC port; a plurality of busses, wherein the plurality of busses electrically connect the plurality of batteries to each other and to the positive DC input and negative DC input of the inverter to effectuate a voltage, and further wherein the plurality of busses are modular and detachable, such that the cabinet is reconfigurable by changing the configuration of batteries of the plurality of batteries each bus connects to which each bus connects.
9. A modular energy storage system comprising: an AC bus capable of connecting to a power grid; and a plurality of modular energy storage cabinets, each cabinet of the plurality of energy storage cabinets comprising: an AC connection port capable of connecting to the AC bus; a plurality of battery modules, each battery module comprising a battery, a positive terminal and a negative terminal; an inverter having a positive DC port, a negative DC port, and an AC port; and a plurality of busses having at least one internal bus; wherein plurality busses electrically connect the plurality of batteries to each other and to the positive DC input and negative DC input of the inverter to effectuate a voltage, wherein the at least one internal bus of the plurality of busses connects the positive terminal of a first battery module to the negative terminal of a second battery module.
10. The modular energy storage system of claim 9 wherein each battery module, of a first cabinet of the plurality of cabinets, further comprises a DC-to-DC converter connected to the battery and to the positive and negative terminal of the respective module.
11. The modular energy storage system of claim 9 wherein the plurality of busses of a first cabinet of the plurality of cabinets, comprises a positive bus and a negative bus, and wherein the negative terminal of each battery module of the plurality of battery modules is connected to the negative DC port of the inverter by the negative bus, and the positive terminal of each of the battery modules of the plurality of battery modules is connected to the positive DC port of the inverter by the positive bus.
12. The modular energy storage system of claim 9 wherein the plurality of busses of a first cabinet of the plurality of cabinets, comprises a positive bus and a negative bus, and wherein negative terminal of the first battery module of the plurality of battery modules is connected to the negative DC port of the inverter by the negative bus, and positive terminal of a last module of the plurality of battery modules is connected to the positive DC port of the inverter by the positive bus, and wherein the at least one internal bus connects each of the battery modules in the plurality of battery modules in series from the first battery module to the last battery module.
13. The modular energy storage system of claim 9 wherein the plurality of busses of a first cabinet of the plurality of cabinets, comprises a positive bus and a negative bus, and the plurality of battery modules comprises a plurality of sets of battery modules, including a first set and a last set, wherein the first and last sets are different; and the negative terminal of the first set is connected to the negative DC port of the inverter by the negative bus, and positive terminal of the last set is connected to the positive DC port of the inverter by the positive bus, and wherein the at least one internal bus connects each of the sets of battery modules of the plurality of battery modules in series from the batteries in the first set to the last set.
14. The modular energy storage system of claim 13 wherein the plurality of battery modules of the first cabinet of the plurality of cabinets further comprises an intermediary set of battery modules between the first set of battery modules and the last set of battery modules.
15. The modular energy storage system of claim 9 wherein a first cabinet of the plurality of cabinets further comprises a circuit breaker in electronic communication with the AC port of the inverter, and having an AC connection port.
16. The modular energy storage system of claim 9 wherein the plurality of busses of a first cabinet of the plurality of cabinets, are modular and detachable, such that the first cabinet is reconfigurable by changing the configuration of batteries of the plurality of batteries each bus connects to which each bus connects.
17. A system for generating and storing energy for a commercial or residential building comprising: a DC power generation system; an AC bus capable of connecting to a power grid; and at least one modular energy storage cabinet electrically coupled to the AC bus, wherein each of the at least one cabinet comprises: a battery bank having at least two batteries, each battery comprising a positive terminal and a negative terminal; at least two busses connecting the batteries in the battery bank to achieve a target voltage, the at least two busses having at least one internal bus; an inverter coupled to the battery bank; and a DC coupler coupled to the DC power generation system, wherein the at least one internal bus of the two busses connects the positive terminal of a first battery bank to the negative terminal of a second battery bank.
18. The system of claim 17 wherein each battery in the at least two batteries is individually coupled to a respective DC-to-DC converter.
19. The system of claim 17 wherein the at least two busses in the at least one cabinet effectuate a voltage of 3000V.
20. The system of claim 17 wherein the at least two busses in the at least one cabinet effectuate a voltage of 1500V.
21. The system of claim 17 wherein the at least two busses in the at least one cabinet effectuate a voltage of 700-900V.
22. The system of claim 17 further comprising an AC power generation system coupled to the AC bus.
23. The system of claim 17 wherein the at least two busses, of the at least one cabinet, comprise a positive bus and a negative bus, and wherein negative terminal of each battery of the at least two batteries is connected to a negative DC port of the inverter by the negative bus, and positive terminal of each of the battery of the at least two batteries is connected to a positive DC port of the inverter by the positive bus.
24. The system of claim 17 wherein the at least two busses, of the at least one cabinet, comprise a positive bus and a negative bus, and wherein a negative terminal of the first battery of the battery bank is connected to a negative DC port of the inverter by the negative bus, and positive terminal of a last battery of the battery bank is connected to a positive DC port of the inverter by the positive bus, and wherein the at least one internal bus connects each of the batteries in the at least two batteries in series from the first battery to the last battery.
25. The system of claim 17 wherein the at least two busses, of the at least one cabinet of the at least one cabinet, comprise a positive bus and a negative bus, and wherein a negative terminal of a first set of batteries of the at least two batteries is connected to a negative DC port of the inverter by the negative bus, and a positive terminal of a last set of batteries of the at least two batteries is connected to a positive DC port of the inverter by the positive bus, wherein the first and last sets of batteries are different, and wherein the at least one internal bus connects each of the batteries in the at least two batteries in sets in series from the first set of batteries to the last set of batteries set of batteries.
26. The system of claim 17 further comprising a control system that electrically connects the DC power generator to the battery bank to recharge the battery bank when the DC power generator is active and the battery bank is below a first power level, and wherein control system electrically connects the inverter to the DC power generator when the DC power generator is active and the battery bank is above a second power level, wherein the second power level is greater than the first power level.
27. A cabinet for a system for generating and storing energy for a commercial or residential building comprising: a battery bank having at least two batteries, each battery comprising a positive terminal and a negative terminal; at least two busses connecting the batteries in the battery bank to achieve a target voltage, the at least two busses having at least one internal bus; an inverter coupled to the battery bank; a DC coupler capable of coupling to a DC power generation system; and an AC connection port capable of connecting to an AC bus that connects to a power grid, wherein the at least one internal bus of the two busses connects the positive terminal of a first battery bank to the negative terminal of a second battery bank.
28. The cabinet of claim 27 wherein each battery in the at least two batteries is individually coupled to a respective DC-to-DC converter.
29. The cabinet of claim 27 wherein the at least two busses effectuate a voltage of 3000V.
30. The cabinet of claim 27 wherein the at least two busses effectuate a voltage of 1500V.
31. The cabinet of claim 27 wherein the at least two busses effectuate a voltage of 700-900V.
32. The cabinet of claim 27 wherein the AC Connection port is further capable of connecting to an AC power generation system coupled to the AC bus.
33. The cabinet of claim 27 wherein the at least two busses comprise a positive bus and a negative bus, and wherein negative terminal of each battery of the at least two batteries is connected to the negative DC port of the inverter by the negative bus, and positive terminal of each of the battery of the at least two batteries is connected to the positive DC port of the inverter by the positive bus.
34. The cabinet of claim 27 wherein the at least two busses comprises a positive bus and a negative bus, and wherein a negative terminal of the first battery of the battery bank is connected to the negative DC port of the inverter by the negative bus, and positive terminal of a last battery of the battery bank is connected to the positive DC port of the inverter by the positive bus, and wherein the at least one internal bus connects each of the batteries in the at least two of batteries in series from the first battery to the last battery.
35. The cabinet of claim 27 wherein the at least two busses comprises a positive bus and a negative bus, and wherein a negative terminal of a first set of batteries of the at least two batteries is connected to a negative DC port of the inverter by the negative bus, and a positive terminal of a second set of batteries of the at least two batteries is connected to the positive DC port of the inverter by the positive bus, wherein the first and second sets of batteries are different, and wherein the at least one internal bus connects each of the batteries in the at least two batteries in one or more sets in series from the set of batteries in the to the batteries in the second set of batteries.
36. The cabinet of claim 27 further comprising a control system that electrically connects the DC power generator to the battery bank to recharge the battery bank when the DC power generator is active and the battery bank is below a first power level, and wherein control system electrically connects the inverter to the DC power generator when the DC power generator is active and the battery bank is above a second power level, wherein the second power level is greater than the first power level.
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December 29, 2021
June 17, 2025
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